内蒙古兴和县曹四夭超大型斑岩钼铅锌金成矿系统年代学及其地质意义

曹四夭斑岩钼矿床位于内蒙古兴和县,是华北克拉通北缘最大的钼矿床。该矿床中部发育斑岩型钼矿体,外围和上部产出热液脉型铅锌金矿体。文章选取1件与斑岩钼矿化共生的绢云母样品进行了40Ar-39Ar定年,获得40Ar-39Ar坪年龄为(144.4±1.2)Ma,相应的39Ar/36Ar-40Ar/39Ar等时线年龄为(146.4±2.2)Ma(MSWD=0.31),将等时线年龄认作绢云母的Ar封闭年龄,表明曹四夭斑岩钼矿化发生在约146 Ma前。选取14件脉型铅锌矿石中的闪锌矿、黄铁矿和磁黄铁矿样品开展了Rb-Sr定年,获得4件闪锌矿的Rb-Sr等时线年龄为(145.1±3.0)Ma(MSWD=0.63);5件黄铁矿的Rb-Sr等时线年龄为(145.2±1.3)Ma(MSWD=0.53);4件闪锌矿、5件黄铁矿和1件磁黄铁矿的Rb-Sr等时线年龄为(145.3±1.0)Ma(MSWD=0.43)。硫化物Rb-Sr定年结果表明曹四夭矿床脉型铅锌矿化形成于约145 Ma前。本次绢云母40Ar-39Ar和硫化物Rb-Sr定年结果表明,曹四夭矿床斑岩型钼矿化和脉型铅锌金矿化为同期产物,两者均形成于晚侏罗世末期,属于同一个斑岩成矿系统。曹四夭矿床硫化物的w(Rb)和w(Sr)分别为0.1867×10~(-6)~1.305×10~(-6)和0.3175×10~(-6)~6.935×10~(-6),Sr同位素初始比值(87Sr/86Sr)i介于0.709 919~0.711 951之间,平均值0.710 952,结合前人获得的辉钼矿Re含量,认为曹四夭矿床的成矿物质主要来源于地壳。     

华北克拉通南缘卢氏多金属矿集区硫化物Rb-Sr定年及地质意义

华北克拉通南缘秦岭成矿带发育大量金矿、钼矿及铅锌多金属矿床。卢氏多金属矿集区位于东秦岭成矿带,主要矿床有夜长坪钼钨矿、八宝山铁铜矿、楼房银铜矿、柳关铅锌矿等。其中楼房银铜矿为热液脉状多金属矿床,矿床赋存于太华群角闪斜长片麻岩中,矿体受构造蚀变破碎带控制,矿床中划分出两个成矿阶段:石英-黄铁矿-黄铜矿组合和石英-黄铁矿-方铅矿-闪锌矿-方解石组合,其中前者是铜成矿阶段,后者为铅锌成矿阶段。柳关铅锌矿为矽卡岩矿床,矿体产于官道口群白云岩与花岗斑岩岩体或隐爆角砾岩接触矽卡岩化带内,矿床划分出两个成矿阶段:透辉石-透闪石-阳起石-石榴石-磁铁矿组合和方铅矿-闪锌矿-黄铁矿-绿帘石-蛇纹石-石英-方解石组合,前者为磁铁矿成矿阶段,后者是铅锌成矿阶段。金属硫化物定年结果表明,楼房银铜矿黄铜矿Rb-Sr等时线年龄为127. 8±3. 1Ma(2σ,MSWD=1. 1),初始87Rb/86Sr为0. 710998±0. 000068;柳关铅锌矿黄铁矿Rb-Sr等时线年龄为124. 8±1. 6Ma(2σ,MSWD=1. 4),初始87Rb/86Sr为0. 711074±0. 000064。研究表明卢氏多金属矿集区内热液多金属矿床形成于早白垩世,其形成与区内早白垩世岩浆活动有关。综合区域地质研究,区内多金属矿床形成于早白垩世与克拉通破坏有关的构造环境。     

Genesis of the Maka Pb-Zn-W deposit in southeastern Yunnan" Constraints from sphalerite Rb-Sr dating,cassiterite U-Pb dating and in -situ S,Pb isotopes of sulfideSCIEI北大核心CSCD

马卡铅锌钨矿床地处云南省马关县与麻栗坡县的南温河交界处,位于燕山晚期老君山复式花岗岩体北缘。野外地质调查发现,该矿床主要发育矽卡岩型、石英脉型铅锌矿化和萤石石英脉型白钨矿化,但它们的形成机制仍缺乏系统研究。本文通过闪锌矿Rb-Sr、锡石原位U-Pb同位素定年和硫化物原位S、Pb同位素分析,厘定了马卡矿床不同类型铅锌矿化年龄,并探讨了其成矿物质来源及成因机制。矽卡岩型和石英脉型铅锌矿石中闪锌矿分别获得了88.9±1.9Ma(MSWD=4.5)和85.18±0.72Ma(MSWD=1.2)的Rb-Sr等时线年龄,同时获得石英脉型铅锌矿石中锡石LA-ICP-MS U-Pb年龄为84.3±4.7Ma(MSWD=0.66)。结果指示锌、锡矿化时代为晚白垩世,矽卡岩型和石英脉型铅锌矿化分别与该区广泛出露的老君山花岗岩(-90Ma)和花岗斑岩年龄(80-86Ma)一致。矿石硫化物原位硫同位素测试结果显示,δ34S值范围为2.53‰-9.65‰,均值为4.7‰,与老君山花岗岩中硫化物硫同位素组成(4.07‰)相似,表明硫主要来源于老君山花岗岩,少部分源自沉积地层;原位铅同位素组成特征也表明矿石铅主要源自老君山花岗岩。综合研究认为,老君山花岗岩体南北缘地区具有相似的成矿地质条件。马卡矿床的形成主要与燕山晚期老君山复式花岗岩体有关,可能经历了与花岗岩有关的矽卡岩型矿化和与花岗斑岩有关的热液充填、交代成矿过程。     

吉林省八家子大型金矿床Rb-Sr同位素测年及同位素地球化学特征

八家子金矿床是华北克拉通北缘夹皮沟金矿带中的重要金矿床之一,赋存于太古宙花岗-绿岩带内。矿体多呈脉状产出,受NW向夹皮沟断裂控制,与中生代正长斑岩有成因联系。本文在八家子矿床选取8件黄铁矿样品开展了Rb-Sr定年,获得Rb-Sr等时线年龄为218.6±1.5Ma(MSWD=1.4),初始Sr同位素比值ISr=0.71047。成矿流体的δ18 OW值为3.2‰~5.1‰,δDW值为-100.7‰~-88‰。成矿流体主要来源于岩浆流体,混合部分变质流体和大气降水。金属硫化物的δ34S值介于-0.2‰~+7.9‰之间,均值+5.7‰,表明硫主要来自深源岩浆。黄铁矿中流体包裹体3 He/4 He值为1.05~1.20Ra,平均值1.13Ra。地幔流体参与成矿作用的比例为11.6%~13.2%,地壳流体占主导地位。八家子金矿的成矿时代为晚三叠世,形成于华北克拉通北缘的碰撞后伸展环境。     

辽宁猫岭大型金矿床成岩成矿年龄及同位素地球化学特征

猫岭矿床是华北克拉通北缘重要的含砷浸染型金矿之一,赋存于元古代辽河群变质岩中。矿体以脉状、似层状、透镜状等产出,受NE向和NW向韧性剪切带及次级断裂控制。选取猫岭矿床10件硫化物样品开展了Rb-Sr定年,获得Rb-Sr等时线年龄为2287±95Ma(MSWD=1.9),初始Sr同位素比值I_(Sr)=0.7117,显示成矿作用发生于古元古代早期。矿区内卧龙泉和猫岭岩体的LA-ICP-MS锆石U-Pb年龄分别为183.0±1.8Ma、128.8±1.6Ma,表明晚中生代岩浆活动与猫岭金矿化无成因联系。成矿流体的δ~(18)O_W值为6.3‰~9.7‰,δD_W值为-97.2‰~-82.6‰,表明成矿流体主要来源于岩浆热液,混合部分大气降水。金属硫化物的δ~(34)S值为+4.3‰~+10.5‰,平均值为+7.9‰,与辽河群盖县组的硫同位素组成相似,表明硫源区为古元古代盖县组。猫岭矿床形成于古元古代伸展构造背景,与辽河群早期的同构造岩浆-热液活动有关,同期形成的强硅化圈保护金矿体免受后期地质作用的破坏。     

内蒙古白音诺尔铅锌矿区三叠纪侵入岩体的发现及地质意义:锆石U-Pb年代学证据

白音诺尔铅锌矿位于大兴安岭南部晚古生代增生造山带,属大兴安岭南段主峰成矿亚带。矿区内,闪长玢岩呈脉状广泛出露,且同铅锌矿体空间关系密切。闪长玢岩通常作为矿床的成矿岩体,并沿用171Ma的成岩年龄。矿床属于与燕山期中酸性侵入岩有关的多金属成矿系列。该年龄值同矿区周围其他矿床成矿岩体的年龄(132.80～142.05 Ma)差别较大。利用锆石LA-ICP-MS U-Pb法对该矿区闪长玢岩和石英二长岩进行了测定,加权年龄分别为(242.3±3.6)Ma(MSWD=2.5,n=7)和(243.0±1.4)Ma(MSWD=1.4,n=12),均为三叠纪构造岩浆活动的产物。研究结果表明,该区在三叠纪处于造山后的伸展构造环境,深部岩浆上涌侵位,系列的构造岩浆活动伴随了以该矿床为例的少数三叠纪矿床的产出。     

黑龙江宁安英城子热液金矿床流体包裹体的氩同位素激光探针定年与成矿时代讨论

英城子金矿床产于张广才岭岩浆构造带内早古生代花岗岩岩体内部的韧脆性剪切带中,矿体由花岗质糜棱片岩、含硫化物石英脉和纯硫化物脉组成,赋矿围岩为晚奥陶世黑云母二长花岗岩。对含金石英脉中石英流体包裹体进行的40Ar/39Ar激光探针定年结果表明:实验室给定的等时线年龄为207±5.5Ma(40Ar/36Ar Int.=410±11,MSWD=44,n=31),剔除相对误差较大的数据点,运用Isoplot程序拟合的等时线年龄为248±39Ma(40Ar/36Ar Int.=344±54,MSWD=0.37,Probability=0.99)。结合区域构造热事件的发育状况,初步确定该矿床的成矿作用发生在晚二叠世末向早三叠世转化阶段或东段的兴蒙造山运动过程。     

豫西吉家洼金矿床成矿时代和成矿物质来源:来自闪锌矿Rb-Sr同位素年龄和Pb同位素的证据

豫西吉家洼金矿位于熊耳山金多金属矿集区西部,是一构造蚀变岩-石英脉型金矿床。矿体产于近南北向断裂带中,在倾向上呈"Y"字型分布,矿化以细脉-网脉状、浸染状黄铁矿化蚀变岩型金矿为主,其次为石英脉型金矿。热液成矿过程包括4个矿化阶段,黄铁矿-石英阶段(Ⅰ)、石英-黄铁矿阶段(Ⅱ)、石英-多金属硫化物阶段(Ⅲ)和石英-碳酸盐阶段(Ⅳ)。本次工作对吉家洼金矿床主要成矿阶段(Ⅲ)的闪锌矿进行了Rb-Sr同位素测年研究,以限定成矿时代。结果获得Rb-Sr等时线年龄为118.2±2.4Ma,表明矿床形成于早白垩世。该年龄与熊耳山地区中的庙岭、祁雨沟、公峪等金矿床的成矿年龄基本一致,对于整个熊耳山地区的金矿成矿年龄具有一定的约束意义。锶-铅同位素研究结果显示,吉家洼金矿的成矿物质为壳幔混源,新太古界太华群基底及其重熔形成的花岗岩体可能为铅同位素的主要物源。我们认为,吉家洼金矿床是熊耳山地区在早白垩世区域性强烈的构造-岩浆-流体活动事件的产物,是整个中国东部金的大规模成矿作用的组成部分。     

鄂西宜昌地区页岩气勘探发现对MVT铅锌矿成矿的指示意义

油气成藏和有机质参与金属成矿的内在联系是近年来国内外地学界关注的热点问题.根据流体包裹体岩相学观察和激光拉曼光谱分析,在鄂西宜昌地区震旦系陡山沱组和下寒武统牛蹄塘组页岩储层及震旦系灯影组MVT（Mississippi Valley type）铅锌矿床中发现了高密度甲烷包裹体,并利用甲烷包裹体的甲烷拉曼散射峰v₁计算了甲烷包裹体的密度;同时采用Rb-Sr、Sm-Nd同位素定年确定了MVT铅锌矿成矿年代.鄂阳页1井陡山沱组页岩石英脉和何家坪MVT铅锌矿方解石样品中甲烷包裹体密度分别为0.237~0.278 g/cm3和0.213~0.271 g/cm3,属于高密度甲烷包裹体.何家坪铅锌矿共生矿物闪锌矿和方铅矿的Rb-Sr等时线年龄为189.1±1.8 Ma,方解石的Sm-Nd等时线年龄为189.9±2.0 Ma,指示铅锌矿形成于燕山早期的构造挤压运动;共生矿物的初始87Sr/86Sr值（0.711 92）和方解石的初始87Sr/86Sr值（0.712 03~0.712 27）指示何家坪铅锌矿成矿流体的Sr同位素主要来源于页岩层.何家坪铅锌矿中捕获的以流体包裹体形式存在的高密度甲烷流体最有可能来源于陡山沱组页岩和/或牛蹄塘组页岩内高密度超压甲烷流体.页岩气层和MVT铅锌矿中高密度甲烷包裹体的发现及MVT铅锌矿成矿时间的确定为探讨有机质参与MVT铅锌矿成矿提供了新证据.      

云南水头山铅锌矿床闪锌矿Rb-Sr定年及其地质意义

水头山铅锌矿床位于保山地块南端芦子园矿集区,区内以发育矽卡岩型和热液脉型两类铅锌矿化为特点.为查明铅锌多金属成矿作用过程,本文对水头山热液脉型铅锌矿床主成矿阶段的闪锌矿开展了Rb-Sr同位素组成测定,获得闪锌矿的Rb-Sr等时线年龄为135.8±4.2Ma(MSWD=1.70,n=6),结合区内其他矿床的成矿年龄,认为...     

上海金山群斜长角闪岩Sm—Nd和Ar—Ar同位素年龄测定

上海地区经钻孔揭示的基底变质地层，即金山群中斜长角闪岩类经全岩Ｓｍ－Ｎｄ等时线法测定其年龄为１２６４±１１３Ｍａ，εｎｄ（ｔ）为１．５±１．９。而从中分选出的角闪石的＾４０Ａｒ－＾３９Ａｒ体系则反映了后期多次热事件的叠加。上述测定结果反映了本区在中元石代的壳增长及显生代期间多期改造的复杂地质演化过程。     

Radiometric dating of the Middle Palaeolithic tool industry and associated fauna of Pin Hole Cave,Creswell Crags,England

Uranium-series dating of derived speleothem suggests that the sediments enclosing a Middle Palaeolithic stone artefact assemblage in Pin Hole Cave probably accumulated after about 64 ka, and ¹⁴C dates indicate a likely age of > 40 ka for the large mammal fauna associated with it. Electron spin resonance data from the fauna conform with these age constraints and are consistent with accumulation between 38 and 50 ka. This evidence supports the view that Britain was recolonised by hominids during Oxygen Isotope Stage 3. Stratigraphically higher stone tool industries demonstrate the local presence of both early Upper and late Upper Palaeolithic cultures. © 1998 John Wiley & Sons, Ltd.     

甘肃巴谢剖面黄土-古土壤的光释光测年研究

光释光（OSL）测年是测定第四纪沉积物年龄的一种新技术。它通过单色光束激发使晶体中储存的电离辐射能释放出来。与热释光（TL）测年相比，OSL测年可以不考虑残留的OSL信号，而且测量具有简便、迅速且准确等优点。本文用细颗粒光释光技术对甘肃巴谢剖面的黄土-古土壤进行了测定，其测年结果与14C测年结果相吻合。这表明，光释光是一项极潜力的年代学技术。     

Linking deformation, migmatite formation and zircon U–Pb geochronology in polymetamorphic orthogneisses, Sveconorwegian Province, Sweden

Absolute ages of migmatization in the polymetamorphic, parautochthonous basement of the Sveconorwegian Province, Sweden, have been determined using U–Pb ion probe analysis of zircon domains that formed in leucosome of migmatitic orthogneisses. Migmatite zircon was formed by recrystallization whereas dissolution–reprecipitation and neocrystallization were subordinate. The recrystallized migmatite zircon was identified by comparison of zircon in mesosomes and leucosomes. It is backscatter electron‐bright, U‐rich (800–4400 ppm) with low Th/U‐ratios (generally 0.01–0.1), unzoned or ‘oscillatory ghost zoned’, and occurs as up to 100 μm‐thick rims with transitional contacts to cores of protolith zircon. Protolith ages of 1686 ± 12 and 1668 ± 11 Ma were obtained from moderately resorbed, igneous zircon crystals (generally Th/U = 0.5–1.5, U < 300 ppm) in mesosomes; protolith zircon is also present as resorbed cores in the leucosomes. Linkage of folding, synchronous migmatization and formation of recrystallized zircon rims allowed direct dating of south‐vergent folding at 976 ± 7 Ma. At a second locality, similar recrystallized zircon rims in leucosome date pre‐Sveconorwegian migmatization at 1425 ± 7 Ma; an upper age bracket of 1394 ± 12 Ma for two overprinting phases of deformation (upright folding along gently SSW‐plunging axes and stretching in ESE) was set by zircon in a folded metagranitic dyke. Lower age brackets for these events were set at 952 ± 7 and 946 ± 8 Ma by zircon in two crosscutting and undeformed granite–pegmatite dykes. Together with previously published data the present results demonstrate: (i) Tectonometamorphic reworking during the Hallandian orogenesis at 1.44–1.42 Ga, resulting in migmatization and formation of a coarse gneissic layering. (ii) Sveconorwegian continent–continent collision at 0.98–0.96 Ga, involving (a) emplacement of an eclogite unit, (b) regional high‐pressure granulite facies metamorphism, (c) southvergent folding, subhorizontal, east–west stretching and migmatization, all of which caused overprint or transposition of older Mesoproterozoic and Sveconorwegian structures. The Sveconorwegian migmatization and folding took place during or shortly after the emplacement of Sveconorwegian eclogite and is interpreted as a result of north–south shortening, synchronous with east–west extension and unroofing during late stages of the continent–continent collision.     

The deglaciation of Clyde Inlet,northeastern Baffin Island,Arctic Canada

The behaviour of ice sheets as they retreated from their Last Glacial Maximum (LGM) positions provides insights into Lateglacial and early Holocene ice‐sheet dynamics and climate change. The pattern of deglaciation of the Laurentide Ice Sheet (LIS) in arctic fiord landscapes can now be well dated using cosmogenic exposure dating. We use cosmogenic exposure and radiocarbon ages to constrain the deglaciation history of Clyde Inlet, a 120 km long fiord on northeastern Baffin Island. The LIS reached the continental shelf during the LGM, retreated from the coastal lowlands by 12.5 ± 0.7 ka (n = 3), and from the fiord mouth by 11.7 ± 2.2 ka (n = 4). Rapid retreat from the outer fiord occurred 10.3 ± 1.3 ka (n = 6), with the terminus reaching the inner fiord shortly after 9.4 ka (n = 2), where several moraine systems were deposited between ca. 9.4 and ca. 8.4 ka. These moraines represent fluctuations of the LIS during the warmest summers since the last interglaciation, and this suggests that the ice sheet was responding to increased snowfall. Before retreating from the head of Clyde Inlet, the LIS margin fluctuated at least twice between ca. 7.9 and ca. 8.5 ka, possibly in response to the 8.2 ka cold event. Copyright © 2006 John Wiley & Sons, Ltd.     

川西北平武地区南一里花岗闪长岩锆石U-Pb定年及其地质意义

川西北平武地区的碧口地块中出露较多的印支期岩浆侵入岩类,但缺乏精确的年代学资料.笔者运用阴极发光技术,对碧口地块西南缘的南一里化岗闪长岩中的锆石进行了细致的内部结构分析,并在此基础上利用LA-ICP-MS锆石U-Pb原位定年技术进行了同位素年龄测定.结果表明,花岗闪长岩中锆石Th/U比值较高,阴极发光图像显示锆石内部发育振荡环带,具岩浆成因特点;南一里花岗闪长岩的结晶年龄为223.1±2.6 Ma(MSWD=1.4),表明其形成时代为晚三叠世早期、南一里花岗闪长岩侵入时代晚于勉略构造带的主碰撞期,侵位于后碰撞环境,或者至少是由同碰撞到后碰撞的转折阶段.     

江西岿美山钨矿矿床的成矿年龄及地质特征

江西省定南县岿美山钨矿区位于南岭东西向构造带东段与武夷山北东-北北东向构造带南段的复合部位,是赣南地区以石英脉型黑钨矿和矽卡岩型白钨矿共生为特征的钨矿床,其是否为南岭地区燕山期的成矿作用,一直没有精确的年代学研究成果。本文采用锆石SHRIMP U-Pb定年和辉钼矿Re-Os同位素定年技术,对岩体年龄和成矿年龄进行了精细的测定,获得成矿黑云母花岗岩体的锆石SHRIMP U-Pb年龄为（157.7±2.7） Ma（n=11,MSWD=1.9）,黑钨矿石英脉的辉钼矿Re-Os等时线年龄为（153.7±1.5） Ma（n=5,MSWD=0.16）,显示岿美山区是华南地区中生代钨矿大规模成岩成矿作用的产物之一。根据“五层楼+地下室”的找矿模型,并结合矿区的最新找矿线索,研究认为在矿区深部岩体的内外接触带具有存在新矿体的可能性,该区深部具有较大的找矿潜力,同时探索性地提出赣南地区石英脉型钨矿深边部存在矽卡岩型钨矿化的可能,对区域钨矿的深边部找矿工作具有指导意义。     

皖南东源含W、Mo花岗闪长斑岩及成矿年代学研究

在详细野外观察、剖面测量和研究分析的基础上,对"江南古陆"东段北缘的皖南祁门东源含W、Mo斑岩体进行了锆石U-Pb测年,重点讨论了成岩成矿关系和成矿物质来源。东源中细粒似斑状花岗闪长斑岩呈小岩株产出,SHR IMP锆石U-Pb测年结果为(146±1)M a,其内辉钼矿Re-Os同位素测年结果为(146.4±2.3)M a,成矿与岩体形成同期,均形成于晚侏罗世。辉钼矿的Re含量(22.02×10-6~98.09×10-6)指示成矿物质来源为壳幔混源。     

稀有金属花岗伟晶岩锆石、锡石与铌钽铁矿U-Pb和白云母~(40)Ar/~(39)Ar测年对比研究——以阿尔金中段吐格曼北锂铍矿床为例

稀有金属花岗伟晶岩年代学是花岗伟晶岩型稀有金属矿床研究的重要内容。目前测年方法较多,但不同方法测试结果的对比研究亟待开展。我们选择吐格曼北花岗伟晶岩型锂铍矿床3条含矿伟晶岩开展锆石、锡石、铌钽铁矿及白云母四种矿物不同方法的测年对比研究。结果显示:1)ρ31白云母-锡石伟晶岩中锡石238U/206Pb-207Pb/206Pb谐和年龄为468±8.7Ma (MSWD=1.1,N=39)、白云母-钠长石-锂辉石伟晶岩中锆石206Pb/238U谐和年龄为458.7±2.3Ma (MSWD=7.2,N=16); 2)ρ38白云母-钠长石-锂辉石伟晶岩中锆石206Pb/238U谐和年龄为454.7±4.0Ma (MSWD=8.0,N=10)、白云母40Ar/39Ar坪年龄为350.2±1.6Ma (MSWD=4.7); 3)ρ87含铌钽铁矿-白云母-石英伟晶岩中铌钽铁矿206Pb/238U谐和年龄为464.1±2.7Ma (MSWD=5.2,N=39)。可以看出,铌钽铁矿与锡石的U-Pb年龄在误差范围内一致,可能代表花岗伟晶岩岩浆结晶的年龄; 2件样品的蜕晶化锆石U-Pb年龄也可以对比,可能代表岩浆锆石蜕晶化后经流体交代作用及重结晶作用导致U-Pb同位素系统重置的时间。白云母Ar-Ar年龄明显晚于铌钽铁矿、锡石和锆石的U-Pb年龄,鉴于ρ38白云母-钠长石-锂辉石伟晶岩脉中白云母与锂辉石发生了强烈变形与蚀变,认为变形的白云母记录的是叠加变形与热液蚀变的时间。由此推断吐格曼北锂铍花岗伟晶岩形成于468～454Ma,这意味着阿尔金山地区中-晚奥陶世可能存在持续时间较长的稀有金属成矿事件。基于花岗伟晶岩矿物成因与吐格曼北锂铍花岗伟晶岩不同方法测年对比结果,可以得出以下结论:铌钽铁矿与锡石的U-Pb年龄可代表伟晶岩岩浆结晶的年龄,蜕晶化的锆石U-Pb年龄记录的是岩浆锆石蜕晶化后经流体交代作用及重结晶作用导致U-Pb同位素系统重置的时间,含钾矿物的40Ar/39Ar年龄能够约束伟晶岩的变形与蚀变年龄;多种定年方法的联合约束可以更好地限定稀有金属花岗伟晶岩的各个阶段成矿事件时间。     

Geochronology of magmatism and mineralization of the Daheishan giant porphyry molybdenum deposit,Jilin Province,Northeast China: constraints on ore genesis and implications for geodynamic setting

Daheishan giant porphyry Mo deposit is located in the Lesser Xing’an–Zhangguangcai Ranges, Jilin Province, NE China. Mineralization is closely related to the Daheishan intrusive complex, which can be divided into Changganglin biotite granodiorite, Qiancuoluo biotite granodiorite, and Qiancuoluo granodioritic porphyry. Four stages of mineralization are distinguished, based on the cross-cutting relationships of mineralized veins. LA-ICPMS zircon U-Pb analysis yields ²⁰⁶Pb/²³⁸U ages of 177.9 ± 2.3 Ma for the Changganglin biotite granodiorite, 169.9 ± 2.3 Ma for the Qiancuoluo biotite granodiorite, and 166.6 ± 4.0 Ma for the Qiancuoluo granodioritic porphyry. Hydrothermal fluids responsible for mineralization evolved from different magmas. Six molybdenite samples yield Re-Os model ages of ~167 Ma. Muscovite from the last mineralization stage gives a ⁴⁰Ar/³⁹Ar plateau age of 163.6 ± 0.9 Ma. Geochronology data indicate that the entire magmatic system lasted for about 10 million years, and the total duration of hydrothermal activity was less than 4 million years. The ε_Hf(t) values of zircons obtained from the Changganglin biotite granodiorite, Qiancuoluo biotite granodiorite, and Qiancuoluo granodioritic porphyry range from 4.5 to 9.1, 5.7 to 10.9, and 4.4 to 7.1, respectively, indicating that they were mainly derived from the depleted mantle, although contaminated by crustal materials to a greater or lesser extent. The formation of the Daheishan porphyry Mo deposit was temporally and spatially related to the amalgamation of Jiamusi Massif and Songliao terrane in the Palaeo-Pacific Ocean regime. Regional Hf isotopic compositions of zircon suggest an episode of crustal growth in the Phanerozoic in the Lesser Xing’an–Zhangguangcai Ranges. Regional Mo mineralization ages suggest a peak of porphyry Mo mineralization in the Jurassic in the Lesser Xing’an-Zhangguangcai Ranges.